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118 Chapter 13 Miscellaneous Conditions potassium begin to produce lengthening PR intervals and nonspecific, but often dramatic, QRS widening. P waves begin to flatten and may disappear altogether. The terminal event is asystole or ventricular fibrillation. Figure 13.3A is the ECG of a 52-year-old white male seen in the emergency department with a serum potassium of 8.1 mEq/L on the basis of renal failure and diabetic ketoacidosis. Note that P waves cannot be seen in most leads, and there is diffuse nonspecific widening of the QRS to over 0.20 s. Figure 13.3B is a tracing taken on the same patient after treatment with intravenous calcium gluconate, bicarbonate, and insulin. Note that although clear P waves Figure 13.3 A. Severe hyperkalemia.ECG of a 52-year-old white male with renal failure and diabetic ketoacidosis,and a serum potas- sium of 8.1. P waves are absent, and the QRS is widened to over 0.20s. B. ECG of the same patient as in Figure 13.3A, but after treat- ment with IV calcium gluconate, insulin, and sodium bicarbonate. Digitalis Effect 119 have not yet returned, the QRS has dramatically narrowed, and T waves in V 4 and V 5 have taken on the tall, peaked appearance typical of lower levels of hyperkalemia. As with hypokalemia, ventricular fibrillation may be the ultimate conse- quence of progressive hyperkalemia. Common causes of hyperkalemia include renal failure,acidosis, administration of aldosterone antagonists, and administration of exogenous potassium. Hypocalcemia The hallmark of hypocalcemia is a prolonged QT interval. Occasionally T wave inversion will also occur, but this is unusual. Clinically significant hypocalcemia is rare, and the primary cause is usually hypoparathyroidism. Hypercalcemia Elevations of serum calcium produce the opposite to those produced by hypocalcemia, namely a shortened QT interval, often with a very abrupt upslope of the T wave. Hypercalcemia is more common than hypocalcemia. Major causes include advanced malignancy, hyperparathyroidism, and sarcoidosis. Drug-Induced ECG Changes Several drugs can produce changes in the ECG, but the most important are digitalis, quinidine, and procainamide. The changes induced by these drugs, although sometimes characteristic, are often nonspecific, and are easily confused with other causes of ECG abnormalities. The primary usefulness in recognizing the abnormalities that can be caused by drugs is to rule out a drug-induced etiology for various ECG findings before concluding that they are the result of primary myocardial disease. In addition, a familiarity with drug-induced ECG changes can aid in suspecting drug toxicity when ECG changes occur acutely in patients on these drugs. Digitalis Effect Digitalis products, even in therapeutic, nontoxic doses, can produce sagging of the ST segment, flattening of T waves, and shortening of the QT interval. The ST depression is upwardly concave, as opposed to its appearance in LVH, for instance,which is upwardly convex.Figure 13.4 shows these typical changes in the ECG of a patient with therapeutic levels of digoxin. Digitalis intoxication can produce multiple rhythm disturbances, includ- ing the classic junctional tachycardia, paroxysmal atrial tachycardia with block, all forms of ventricular ectopy, and all forms of heart block. 120 Chapter 13 Miscellaneous Conditions Quinidine Effect The primary effect of quinidine is on T waves and the QT interval. T waves become widened, flattened, and ultimately inverted. Marked lengthening of the QT interval can occur and can contribute to the proarrhythmic effect sometimes noted with quinidine. In addition, significant widening of the QRS occurs at toxic levels. Figure 13.5 shows the precordial leads of a 75-year-old white female who had recently been started on quinidine for atrial fibrillation.This tracing I II aVR aVL aVF V1 V2 V3 V4 V5 V6III Figure 13.4. Typically sagging ST segments of digitalis effect. Note that the patient is in a junctional rhythm. Figure 13.5. Precordial leads of a 75- year-old white female on quinidine just after cardioversion from ventricular fibrilla- tion. Note the prolonged QT interval and the flattening and widening of T waves. Considerable muscle artifact is present. Intracranial Hemorrhage 121 was taken just minutes after conversion from an episode of ventricular fibrillation precipitated by the proarrhythmic effect of quinidine. Note that the QT interval is prolonged and that the T waves are flattened and widened. Procainamide Effect The primary effect of procaineamide is widening of the QRS at toxic doses. An increase in QRS duration of 50% or more is one of the endpoints for procainamide administration. Intracranial Hemorrhage Cerebral hemorrhage or other causes of rapid rises in intracranial pressure can produce bradycardia, widening of the T waves, and T wave inversion across the precordial leads. Such changes are an ominous prognostic sign. Figure 13.6 shows the tracing of an elderly white female with an ultimately fatal extensive cerebral hemorrhage. I II aVR aVL aVF V1 V2 V3 V4 V5 V6III Figure 13.6. ECG tracing just before death of an elderly white female with a massive cerebral hemorrhage. Note the deep, sym- metrical T wave inversion, particularly across the precordial leads. 122 Chapter 13 Miscellaneous Conditions Diffuse Low Voltage Low voltage throughout the 12-lead ECG can be seen with hypothyroidism, pericardial effusion, and diffuse cardiomyopathy of ischemic or other origin. Pericarditis The ECG changes of acute pericarditis, like those of AMI, go through an evolutionary process over a period of weeks. But, as you will recall from the discussion of the differential diagnoses of ST elevation in Chapter 9, there are significant differences that usually permit us to distinguish between the two. ST elevation is the usual initial hallmark of both pericarditis and AMI. The ST elevation of pericarditis, however, is usually upwardly concave, widespread throughout all leads, and without reciprocal ST depression. T wave inversion follows ST elevation as the ST segments return to base- line, but the Q waves seen with AMI never develop. Another interesting and unique finding with pericarditis is depression of the PR segment. Figure 13.7 is the ECG of a 37-year-old white male with acute viral pericarditis. Note that the PR segments are depressed below the base- line and that there is widespread, upwardly concave ST elevation, without reciprocal depression and without Q wave formation. Acute pericarditis often undergoes ECG evolution, much as does AMI, except for Q wave formation, which does not occur with pericarditis. ST-segment elevation will show resolution, however, and, as with AMI, T waves may invert. I II aVR aVL aVF V1 V2 V3 V4 V5 V6III Figure 13.7. Acute viral pericarditis in a 37-year-old white male. Note the widespread, upwardly concave ST elevation, depressed PR segment, and absence of Q waves or reciprocal depression. Hypothermia 123 Wolff–Parkinson–White Syndrome Wolff–Parkinson–White syndrome is the result of a congenital accessory pathway to the ventricles that bypasses the AV node, resulting in preexcita- tion of the ventricles. The impulse still goes down through the AV node nor- mally, but also goes down the accessory pathway, which conducts much faster than the AV node. The result is that the impulse gets to the ventricles early via the accessory pathway, producing an early slurred upstroke of the R wave called a delta wave (Figure 2.4). This early delta wave also produces a short PR interval and widening of the QRS. Often, however, the remainder of the QRS after the delta wave looks normal because, in many instances, most of the ventricular muscle is still depolarized via the normal conduction system.In other cases,a large amount of muscle may be depolarized by slow muscle-to-muscle conduction initi- ated by the accessory pathway and may produce a QRS, an ST segment, and T waves looking more like a BBB pattern. Figure 13.8 is the tracing of a 44-year-old white male with a history of WPW syndrome. Note that the PR interval is short and there is a clear delta wave seen in most, but not all, leads. In the case of this particular patient, the remainder of the QRS looks normal. Hypothermia Marked hypothermia produces prominent bradycardia, first degree AV block, and QRS abnormalities at the J point (junction of the QRS and ST segment) called J waves or Osborn waves. Characteristically, there is J point elevation, and the Osborn wave then slopes down over approximately 0.04s into the ST segment. I II aVR aVL aVF V1 V2 V3 V4 V5 V6III Figure 13.8. WPW syndrome with a short PR interval, and delta waves seen in most leads. 124 Chapter 13 Miscellaneous Conditions Figure 13.9 shows a rhythm strip from a 32-year-old male who presented with a heroin overdose after being outside all night. His core body temper- ature at admission was 84.6 degrees Fahrenheit. P waves are of low ampli- tude and difficult to discern. Osborn waves are prominently visible as shown by the arrow. Figure 13.10 is the full 12-lead tracing after substantial re- warming. Heart rate has increased and P waves are now more visible, but first-degree heart block remains, and prominent J waves are still present. RM 14 08:45 21JAN2006 II MON HR= 26 A = 0 *ALARM* LO LIMIT=40 SPEED = 25 MM/SEC CHAN 2 – LEADS OFF RESP = 14 SPO2 = ??? NIBP = 08:40 NO READING mmHg V Figure 13.9. Osborne waves or J waves associated with a core body temperature of 84.6°F in a 32-year-old male heroin overdose patient suffering from exposure. Note that the rate is slow, P waves are difficult to identify, and there is J-point elevation, with the Osborne wave then sloping down into the ST segment over about 0.04 s. I II aVR aVL aVF V1 V2 V3 V4 V5 V6 III Figure 13.10. Twelve-lead ECG of the same patient after substantial rewarming. Note that the P waves are now quite visible, but J waves remain, although they are less prominent than in Figure 13.9. This section is designed to give you some practice in implementing your newfound knowledge in making clinical decisions regarding the patient with a potential acute coronary syndrome, much as ACLS megacodes permit you to practice resuscitation. There are 12 practice case presentations. You will have the opportunity to make decisions in a sequential fashion, much as you would do in real-life clinical situations. Sometimes you will be functioning in the prehospital environment, and sometimes in the emergency depart- ment or coronary care unit. For purposes of this section you should assume that the phrase prehospital thrombolytic protocol refers to (1) starting two IVs, (2) drawing blood specimens for laboratory analysis in the process of starting the IVs, and (3) administering one aspirin to be chewed—all of these in preparation for potential thrombolysis in the emergency department. Because a decision to implement thrombolysis is often more complex than a decision to refer the patient to an interventional cardiologist for emergent PCI, most of the following scenarios that involve a patient with STEMI assume that interventional cardiology is not immediately available, or is too far away to warrant the diversion of an ambulance. Policies regarding the authority of individual paramedics, nurses, and even physicians to initiate procedures or therapy vary from jurisdiction to jurisdiction. Assume for the purposes of this section that you always have the authority to proceed without consulting a higher authority when pre- sented with diagnostic or therapeutic options. You should find it to be fun. Case 1 You are functioning as a prehospital ACLS provider today in a community more than 2 hours away from the closest cardiac catheterization facility. Acute STEMIs are therefore treated in your local hospital with thrombolytics. You are dispatched to a local accounting firm to help a 39-year-old black male with a chief complaint of retrosternal chest discomfort with minimal radiation to the left shoulder. The pain came on while he was sitting at his desk, is described as a pressure, and has been present for a little over 3 hours. He admits to mild nausea, but denies vomiting, diaphoresis, or shortness of breath. He has not 125 14 Case Presentations 126 Chapter 14 Case Presentations tried antacids or nitroglycerin for relief. He awoke with a similar discomfort about three nights ago, went into the bathroom and got a drink, and then lay down and fell asleep again. He has had no exertional chest discomfort with exercise such as mowing the lawn with a push lawnmower. He has been told in the past that his blood pressure was “a little high,” but no medications were prescribed. He smokes one pack of cigarettes daily. His father died quite suddenly in his early 50 s. Physical examination reveals a mildly obese black male who appears anxious. Pulse, 80. Respirations, 20. BP, 184/112. His skin is warm and dry. He has no jugular venous distention. The lungs are clear. Hearth rhythm is regular, and the heart tones are not muffled. You can hear no gallop, murmurs, or friction rubs. He has no peripheral edema. 1. With regard to the pain, you conclude that: a) the history is sufficient to be compatible with ACS. b) the history is not compatible with ACS. 2. With regard to the physical examination, you conclude that: a) the physical examination lends support to the diagnosis of ACS. b) the physical examination neither confirms nor denies the possibility of ACS. 3. Your first procedural step should be to: a) give 0.4mg sublingual nitroglycerin. b) start a medical IV, attach the patient to a cardiac monitor, and start O 2 . c) perform a 12-lead electrocardiogram. d) question the patient regarding contraindications to thrombolytic therapy. 4. Your second procedural step should be to: a) give 0.4mg sublingual nitroglycerin. b) start a medical IV, attach the patient to a cardiac monitor, and start O 2 . c) perform a 12-lead electrocardiogram. d) question the patient regarding contraindications to thrombolytic therapy. 5. Your third procedural step should be to: a) give 0.4mg sublingual nitroglycerin. b) start a medical IV, attach the patient to a cardiac monitor, start O 2 . c) perform a 12-lead electrocardiogram. d) question the patient regarding contraindications to thrombolytic therapy. You have performed a 12-lead ECG (Figure 14.1). Questioning conducted during performance of the ECG revealed that the patient had a hernia repair 2 years ago. He admits to an allergy to aspirin and states that he breaks out in hives when he takes the drug. 6. Upon completion of the ECG, you quickly note that the patient’s elec- trocardiogram shows: a) a normal axis. b) RAD. Case 1 127 c) LAD. d) an indeterminate axis. 7. With regard to contraindications to aspirin, you conclude that: a) contraindications exist. b) no contraindications exist. 8. With regard to contraindications to thrombolytic agents, on the basis of currently available information you conclude that: a) absolute contraindications exist. b) relative contraindications exist. c) no contraindications exist. 9. Upon contacting medical command by radio, you report that the ECG shows: a) an acute inferior STEMI. b) an acute anterior STEMI. c) an inferior myocardial infarction that may be old. d) an anterior myocardial infarction that may be old. e) benign early repolarization changes. f) a LBBB simulating anterior STEMI. g) acute pericarditis. h) a normal ECG. i) nonspecific ST changes. 10. Your field assessment, as reported to medical command, is that: a) sufficient evidence of STEMI exists to recommend thrombolytic therapy and to institute the prehospital thrombolytic protocol. b) sufficient evidence of STEMI exists to recommend thrombolytic therapy with the exception of aspirin, if relative contraindications can be removed. c) evidence of STEMI exists, but absolute contraindications prohibit thrombolytic therapy. I II aVR aVL aVF V1 V2 V3 V4 V5 V6III Figure 14.1. [...]... sublingual nitroglycerin d) perform a 12-lead ECG Your quick preliminary physical exam reveals diaphoretic skin, no jugular venous distention, and clear lungs Vital signs are a pulse of 78, respirations at 24, and BP of 1 08/ 86 A 12-lead ECG has been performed and is reproduced in Figure 14.3 3 On the basis of currently available information, you conclude that thrombolytic agents, if necessary, would be:... monitoring station doing chart work when you hear his patient call bell As you enter the room you note that he remains in normal sinus rhythm and that his monitor is displaying a blood pressure of 1 08/ 86 As you grasp his hand and ask what he needs, you note that his skin feels cool and diaphoretic Mr Fitzgerald stoically reports that his retrosternal pain of earlier this evening returned approximately... developing Q waves Thrombolytic agents, on the basis of available information, are relatively contraindicated because of the patient’s blood pressure in excess of 180 /110, but should be administered if treatment is successful in reducing blood pressure to 180 /110 or below This can often be accomplished simply with morphine and nitroglycerin Additional beta blockers should also be considered because she remains... nonrebreather mask, placed him on a cardiac monitor and pulse oximeter, and started an IV of NSS The monitor shows him to be in normal sinus rhythm with occasional unifocal PVCs His oxygen saturation is 88 % on the nonrebreather mask 135 ... conclude that: a) sufficient evidence of STEMI exists to initiate thrombolytic therapy b) sufficient evidence of STEMI exists to initiate thrombolytic therapy if blood pressure can be reduced to below 180 /110 c) evidence of STEMI exists, but absolute contraindications prohibit thrombolytic therapy d) evidence of STEMI exists, but relative contraindications rule out thrombolytic therapy e) insufficient... thrombolytic therapy at present, but the index of suspicion is still high enough to warrant monitoring and repeat ECGs while a workup is proceeding Answers and Case Discussion 1 a 2 a 3 b 4 c 5 c 6 b 7 b 8 b 9 a 10 b This middle-aged white female had significant risk factors in the form of obesity, hypertension, and diabetes, even though no family members were known to have had a myocardial infarction Although...1 28 Chapter 14 Case Presentations d) evidence of STEMI exists, but relative contraindications rule out thrombolytic therapy e) Insufficient evidence of STEMI exists to recommend either thrombolytic therapy... but the index of suspicion is still high enough to warrant implementation of the prehospital thrombolytic protocol, with the exception of aspirin Answers and Case Discussion 1 a 2 b 3 b 4 c 5 a 6 a 7 a 8 b 9 e 10 f This 39-year-old man had the significant risk factors of a family history of cardiovascular disease, cigarette smoking, and hypertension Although vomiting, diaphoresis, and shortness of breath... relative contraindication to thrombolytic agents, although one could still be administered if the projected benefit outweighed the risk or if treatment was administered and resulted in the BP falling below 180 /110 Aspirin is, of course, absolutely contraindicated because of the clear history of allergy, and in this case, one might want to use clopidogrel We are, thus, left with a patient with significant risk... are again assigned to an ACLS unit in a large metropolitan area It is 7:45 AM Your unit is dispatched to an apartment building for chest pain and shortness of breath In a fourth floor apartment you find 80 -year-old Mr Burgman wearing pajamas, sitting in his bedroom in a reclining chair You immediately note that he appears very short of breath Light from the bare overhead bulb is reflecting off his wet . skin, no jugular venous distention, and clear lungs. Vital signs are a pulse of 78, respirations at 24, and BP of 1 08/ 86. A 12-lead ECG has been performed and is reproduced in Figure 14.3. 3. On. s. Physical examination reveals a mildly obese black male who appears anxious. Pulse, 80 . Respirations, 20. BP, 184 /112. His skin is warm and dry. He has no jugular venous distention. The lungs are. because of the patient’s blood pressure in excess of 180 /110, but should be administered if treatment is successful in reducing blood pres- sure to 180 /110 or below. This can often be accomplished